Effect of Isopropyl Peptization on Surface Particle Growth of Sol-Gel Derived Anatase: X-ray Crystallographic Analysis and Revealed on Transmission Electron Microscopy
Md. Tarikul Islam, Md. Ashikur Rahaman, Shanawaz Ahmed, Mist Toma Khatun, Sahil Aman, Taiful Bayzid, Aslam Ahmad, Md. Al-Amin, Md. Ashraful Alam
Abstract
Titanium isopropoxide (TTIP) mediated, a unique, simple, unparalleled technique was utilized to produce a highly crystalline anatase. The crystallographic parameters were investigated by X-ray diffraction (XRD) and transmission electron microscopy (TEM) technique. XRD pattern confirmed the presence of tetragonal symmetrical crystal structure with lattice parameters a=b= 3.7875 Å, c= 9.4949 Å; α=β=γ= 90.0°. The strongest diffraction recorded at 2θ= 25.28 0 predominant (101) plane. Lattice strain was calculated 0.83 % with the volume 136.206 Å 3 and average density of dislocations 7.339 × 10 -3 nm -2 . The calculated atomic packing factor was 60.75 % for dense crystal, micro-strain 0.00109 and surface area to volume ratio was 0.126 nm -1 and Young’s modulus 533.028 GPa respectively. The synthesized anatase demonstrated a degree of crystallinity of 65.89 % among ICDD standard reference 64.51 %. The SEM explored the microstructure which was uniformly dispersed across the surface with no agglomeration and particles are evenly dispersed with a small sizes spherical. SEM-EDS revealed that Ti= 61.64 % and O= 38.36 % which conformation unified nanoparticles. TEM topography revealed consistent crystal development, with a crystallite size of 10.62 nm and an average particle size of 13.48 nm. The TEM-SAED pattern verified that the predominant (101), (004), (200), (105), (211), (204), (116), and (220) crystal planes were dominated with high crystallinity. HR-TEM showed the d-spacing 0.352 nm (101) while SAED revealed in 0.357 nm (101). Additionally, TEM couple EDS showed that the crystalline nanoparticles were entirely 100.0 % pure. These results contribute to a better understanding of topography and structural characteristics of anatase nanoparticles and this contributed prospectus.